Maneuvering mechanism for internal-combustion engines



May 26, 1925.

J. A. SEYMOUR ION ENGINES MANEUVERING MECHANISM FOR INTERNAL COMBUST l0 Sheets-Sheet l Filed MaIOh 15, 1924 INVENTOR A ATTORNEYS l wg n..MI

U A n f fr lll A. I s@ May 26, 1925.

J. A SEYMOUR MANEUVERING MECHANISM FOR NTERNAL CO MBUSTION ENGINES INVENTOR ATTORNEYS May 26, 1925. 1,539,050

' J- A. SEYMOUR MANEUVERING MEGHANISM FOR INTERNAL coMBUsTIoN ENGINES Filed March l5. 1924 l0 Sheets-Sheet 5 ATTORNEYS May 26, 1925.

Filed Maron -15`, 1924 1o sheets-sheet 4 jm@ l ATTORNEYS Mgy 26, 1925. 1,539,060

J.' A. SEYMOUR MANEUVERING MECHANISM FOR INTERNAL GOMBUSTION ENGINES `INVENTOR I ,9m-.14 I MW IM May 26, 1925.l 1,539,060

J. A. SEYMOUR- MANEUVERING MECHANIASM FOR INTERNAL COMBUSTIONVENGINES @ffy y Ziff Filed'marqh 415, 1924 1o Sheng-sheet a May 26, 1925. 1,539,060 J. A. SEYMOUR MANEUVERING MCHANISM FOR INTERNAL COMBUSTIION ENGINES Filed March 15J 1924 l0 Sheets-Sheet 7 Ii f a v ,fl/"""Ozl-l-lg U INVENTOR v BY y Zta ATTORNEYS May 26, 1925. Y 1,539,060

J. A. sEYMouR MANEUVERING MECHANISM FOR INTERNAL COMBUSTION- ENGINES Filed March l5. 1924 l0 Sheets-Sheet 8 f J INVENTOR BY CX ATTORNEYS May 26, 1925. 1,539,666

' J. A. SEYMOUR MANEUVERING MECHNISM FOR IINTERNAL COMBUSTION ENGINES Filed March 15, 1924 .1Q .sheets-sheet s ff w 226/ f2? 2;/ wia/) j? v3? Y Z/ Z7 INVENTOR A oRNEYs May 26, 1925. 1,539,060 i' J. A. SEYMOUR MANEUVERING MECHANISM FOR INTERNAL COMBUSTION ENGINES Filed March l5, 1924 10 Sheets-Sheet l0 INVENTOR BY 72a/ ATTORNEYS Patented May 26, 1925.

JAMES A. SEYMOUR, 0F AUBURN, NEW YORK.

MANEUVERING MECHANIM FOR INTERNAL-COMBUSTION ENGINES.

Applicationled March 15, 1.824. Serial No. 699,587.

To all whom t 'may concern.'

-Be it lrnown that I, JAMES A. SEYMOUR, a citizen of the United States, residing at Auburn, in the county oit' Cayuga and Stato ot New York, have invented new and useful improvements in Maneuvering ltlechanism for internal-Combustion Engines, of which the `following is a speciiication.

The invention relates to a novel and improved combination ot mechanisms eliqecting the control or maneuvering of internal combustion reversing engines such as are used for ship propulsion among other purposes. The maneuvers -include necessarily starting, stopping, phase reversing and control of speed which latter is etlected by changing the effective torque of en gine, by varying the amount of fuel ted to engine.

ln this particular class ot engines to which my invention is especially applicable, each of the various maneuvers are effected by a sequence ot more or less independent operations with individual mechanisms so handled that while each operation is being performed none ot the other operations of the necessary sequences shall take place which might interfere with the success of the maneuver and one of the main objects of the invention is to so control all of the various sequences of the various operations tor the various maneuvers, which may be desired,

that the manual control thereof maybe assat'e and simple as possible and preferably by a single maneuver actuating member.

Other operations in addition to those mentioned above should be controlled by this maneuver actuating member on certain engines, especially those of large size, which may be unnecessary or undesirable on other engines. This maneuver actuating member may constitute a manually operated hand control lever in the case ot small engines where not too much vpower is required; otherwise the maneuver actuating member should be driven by a prime mover or some sourceot power, the motion of which is controlled by the hand control lever by some form otfollow up device such as is used with steam and electric steering devices for ships or other well known mechanism, provided the etlect accomplished is to cause a pointer moving' with the Vmaneuver actuating member to follow up' and eventually occupy the same relative positions as the hand control lever and to remain stationary in this position until a further movement of hand control lever takes place.

While thevetlect is the same for manual and power drive just described since the operator with power drive need use only a very slight effort to move hand control lever, regardless of size of engine or power required to move maneuver actuating member, which becomes too great for manual eftort with reasonable speed of maneuvering for engines of larger sizes, the power drive is also illustrated because some additional advantages flow from the invention when power drive is used.

For instance, while manual operation by a. single lever controlling all maneuvers possesses the advantages ot less liability ot a wrong move by the operator, also of no chance ot starting one of the operations out of proper sequence or before the preceding one is finished in which case interference and a breakage of mechanism will take place unless a somewhat elaborate system ot interlocking safety devices are used yet on the other hand,.where the various operations are controlled by a plurality otindividual manually operated levers each handling one or more operations, this latter plan, which is the one in common use and not novel, does give some offsetting advantage in the simplicity of mechanism and cheaper construction (at least Where no interlocking, safety' devices are used) but is by no means assate or convenient. Then one or more of the operations require more power than is practicable with manual operation so that each individual lever requires a separate source of power and for some maneuvers a follow-` up device in addition, the advantage of simplicity of mechanism is with a single power driven control as already described, and all the advantages of the manually operated single control lever remain in many respects with increased value.

In the application of my invention which will be illustrated later, the range of movement of the actuating member ,is thus di-y vided into sections, corresponding to the periods of `operation ol: variousvv individual maneuvering mechanisms, as follows;

Three contiguous se .ions which may be termed the phase reversing sections or group of sections, which group may be broadly regarded as a phase reversing section. i

2. The series; ot positions or stations corresponding to graduated amounts of fuel feed occupy a section which may be termed the ahead running section7 for ahead motion, and a similar astern running section for a. corresponding astern motion.

3. rlhe actuating member also has two starting sections, each section having a corresponding starting station Within its rangeand being adjacent tothe correspending running section, for aheadl and astern starting.

Before describing in, detail the application of theA invention illustrated it may be better to descibe in general terms one of its principal featuresgvnamely, the use of a number of' vvrist plate motions in series in the connecting trains of mechanism so that the .motion of the actuating member at the source ot' poiver, which normally is substantially ot even velocity througl'iout its maximum amplitude, may be by various trains of simple Working levers a rl connecting linlrs, distorted and transiormed so that a pause or dwell Without substantial motion may be effected for a period ot time, during saidv maximum amplitude ot motion, at the delivery end of said train of levers and connecting links at which point, outside of the said period of pause, the even motion of the driving mechanism will be transmitted more or less unchanged.

The use in a valve gear1 of such a series of Wrist plate motions in series as a` means oi securing an intermittent mot-ion for the valves of a steam engine, is described in Letters Patent #1,111,327, issued to me en September 22, 1914.

To explain further, the oldest known example of aV simple Wrist plate motion is represented by part of the drive or" an exhaust valve of a Corliss engine, that is, by the Wrist plate, the exhaust arm and the link connected to each by suitable pins, one on the Wrist plate and one on the exhaust arm. The Wrist plate is oscillated through a convenient angle by a. connection to an. eccentric on the engine shaft. The pin on the Wrist plate is usually so placed that at the extremev of angular movement ot Wrist plate When the exhaust valve is closed, the longitudinal axis of connecting link, iifextended7 Will pass through the axis ot' rotation of Wrist plate,` that is, in a plane perpendicular to the last namedaxis, aproject-ion of this axis, the centre of this vconnecting pin, and the axis of connecting link -ill all lie in the same straight line. The effect ot this is to cause a diminution in the motion of the exhaust valve, rigidly attached te and revolving With exhaustr arm,

when closed and subject to pressure of the steam in cylinder and thus to greatly reduce friction and Wea-r. Any pair of rocking levers with a connecting link so disposed may be termed a wrist plate motion, and are so designated in my Letters Patent No. 1,111,327, above referred to.

ln the case of a Corliss engine, the extreme orp Wrist plate or driving lever angular movement, when exhaust valve is closed, usually takes place as described above. In other applications Where a still greater diminution of motion is of travel, the extreme` of angular movement is made-fon the other side ot the straight line position as described above, from the principal amount of movement. The movement of the driving lever for some distance on-each side of this straight line position" gives no appreciable motion to driven lever. Nearly one-half of the angular movement of `the driving lever may be substantially blotted out in movement of the driven lever, With movement during the other half ta-nsmitted` almost unchanged, by having one-half of that part of movement of driving lever, Which itis desired to suppress, occur on each yside of the straight line position.

The driven lever of vany Wristplate motion may be used as the driving lever for a succeeding wrist plate motion in series by properly disposing the drivenv lever of the second Wrist plate motion, or it the positionA of driven lever of second motion is more or less fixed, a second driving lever may be attached so as, to oscillate With the driven lever oi" the rst motion, properly disposed With reference to the second driven lever. In this Way any length of pause at either or both ends of movement may be secured by thus using a sufficient number ot Wrist plate motions.

lf' the arrangement oi the driven lever, instead` of being symmetrical, is such that a greater part of its motion is on the side of its position, when at right angles to the connecting link, nearer to the driving lever, some additional distortion may ensue, but of limited amount unless carried' to an extent that introduces undesirable friction and stresses. By using a greater amplitude of oscillation on the actuating member than is customary with a Wrist plate motion, further though, in some ways similar effects, may be secured, and as ivill be illustrated later, by a proper disposition of leversand links and the use of a plurality ot series of wrist plate elects, asmany periods of no motion as desired, at various points ot travel of driving mechanism as desired, and for the length of perioddesired, may be obtained., j

Referring to the drawings:

Fig. l is a view in section through one desired, at this end llO engine cylinder and crank case of a Diesel six cylinder engine of the usual type, omitting details not necessary for the understanding` of the present invention, and showing in end elevation the maneuvering shaft and` trains of mechanism therefrom for effecting the maneuvers of starting and control of fuel feed to said engine. Also in this view appears in section the fuel feed pump for said Vig'. l is a. detail projection at right angles to Fig. I of the linlrs 141 and 43;

Fig. ll is a similar View of said engine and cylinder in end elevation, with a partial section through the cylinder head in a plane parallel to and at one side of the section in Figi: l to illustrate typical valve mechanism for an exhaust or inlet valve. ln this view also appears the maneuvering` shaft in a dif ferent position than shown in Fig. l and having connected thereto a. different train of mechanism for manipulating the valve cani rollers in effecting the reversal of said engine as will be later described. It will bel understood that the train of mechanism here shown lies directly behind and parallel to that shown in Fig. l.

Fig. lll is anotherl end view of the same cylinder showingstill another train o-f mechanism connected to said maneuvering` shaft, which lies behind the train of Fig. Alil. The maneuvering shaft here shown is in still another position and the train of mechanism, is for shifting the cam shaft endwise as will be later described, for effecting` the reversal of said engine;

Fig. IV is a detail view partly in center section of the same cylinder head for showing` the fuel inlet valve and mechanism for controlling same;

Fig. V is detail view of certain parts in Fig. lll and Fig. lV, and projected in a plane at right angles to the latter, showing further mechanism connected therewith;

Fig. Vl is a det-ail lin end elevation of a portion of the engine frame'showing in face view a hand controller for power' control by follow-up mechanism.

Fig. VH is a detail view of parts directly behind that of Fig. VI showing the power drive for said follow-up mechanism.

lFigs. Vlll'and 1X are details in different positions of a switching plate for the follow-up` control mechanism;

Fig'. X is an enlarged detail partly insection of a modifie-d form of follow-up control mechanism embodying;- crtain automatic features hereinafter described;

Fig. Xl is a horizontal section `through the'controller casing1 of the control mechanism shown in Fig; X.

Fig. XH is a detail section similar to Fig. X showing relative position of parts not appearing in said latter ligure;

Figs. XIII and XV are views similar to positions of other parts corresponding tothe positions shown in Figs. Kill and Ir; and

Figs. XVH to KKH are detail views illustrating,` a further modified form of follow-up control mechanism operating to per form the same functions as the mechanism of ifipj. X to XVI, but in a different manne n lllhile the drawings illustrate an arrangen'ient not the most desirable for ypractical construction and use, or for proportions and size of parte, the disclosure adopted enables the functions of the various parts to be much more easily described and understood.` rlhe center lines (bro-lien and dotted) indicating different positions of the actuating' member corresponding to different stations of ma.- neuvering hand lever are designated by capi tal. letters.

ln the type ofengine illustrated, the van rions nianeuvers are accomplished. as fol lows :v

First; the engine is stopped olf the supply of fuel.

' s. XlV and Kill are details showing by shutting Second; it is started by throwing into gear i the starting valves as well as fuel pump, and fuel, air inlet, and exhaust valves, if the latter are not already in gear, the starting` valves only being; thrown out as soon as engine has started sufficiently to insure run# ning.

Third; it is reversed by stopping engine as above if running, and then swinging reach rods so that the cam rollers are removed from the set of actuating cams in use for all of the valves except starting.;1 cani rollers already out of gear, then moving the camshaft lengthwise so as to bring a. second set of cams, phased to Igive a reversed motion to engine, in line with reach rods and finally swinging` back reach rods 'so as to cause all the cam rollers except starting cam rollers to engage their respective cams, the engine being started if Idesired as eescribed above.

In Fig. I, the principal `parts are indicated as follows: a is the base frame and part of the maneuvering gear casing; l), the crank case also integral with parts of the maneuvering gear casing; c, the engine cylinder; cl, the cylinder head; e, the piston; f, the piston rod; g, the crosshead; 72., the connecting rod; and y', the main crank shaft of the engine. p

The starting valve l is situated in the starting valve cage Q, part of which forms the seat for the valve. Compressed air of suitable pressure for starting the engine is supplied from a suitable reservoir, not shown, through a supply pipe 3 and a starting air shut-off valve 4:. The means of compressing and delivering this compressed air to the engine may be either driven by the engine or .independently driven and are not shown. This is-also true of the high pressure air supplied to the fuel valve cage 5 as described later.

The starting valve l is seated by spring 6 and opened by train of mechanism consisting' of stein 7, lever 8 pivoted at 9 and connected to the reach rod l which carries the cam roller l1, driven by the starting cams 12a' and 12b mounted upon camshaft 13 journaled in cam bracket i4, The nose of starting cam 12b for astern motion is situated behind that for forward motion at 12a.

The starting cam roller 1l can be disengaged entirely from its cam l29L by swinging the reach rod l0 so tl at the lower connected end thereof will occupy position B7 instead of S7 as shown. This is accomplished by turning the starting lay shaft l5 so as to move the'rocker arm i6 which is rigidly mounted on starting lay shaft l5 and is connected to reach rod l0 through link 18 to bring its lower end from position S6 to BG, The mechanism for thus moving the n starting lay shaft will be described later.

rlhe air starting' shut off valve body 2OV is provided with a spring closed valve 4 closed; b v spring 2l and opened by moving a slotted link 22 to posit'on shown which acts on the shut off valve 4 throughY rocker 23, pivoted at 24 and link 25. rllhe slot in link 22 is so situated that the shut olf valve 4 is opened only when the operating end of link 22 approaches very near to the position shown at Swand the shut olf valve is unaffected at other points in travel of link 22 from positions between S8, FS and RS because at such times the pin slides freely in the slot. The means used for moving link 22 will be described later.

vThe fuel valve cage 5 contains the fuel valve and atomizer (shown more in detail in Fig. lV) and is supplied with fuel oil through deliver pipe 26 by fuel pump 27 mounted on an extension of maneuvering case Wi. The fuel pump is provided with delivery valve 28, suction valve 29, supply pipe 30 from suitable fuel oil reservoir, not shown. rllhe fuel pump plunger 3l is driven through the pin 32 by the eccentric strap 33v surrounding the eccentric 34. rlhe eccentric is mounted upon an inclined cylindrical boss forming` as an integral part of the center shaft 36 with a spline 37 so that the eccentric 34 must turn with center shaft wnereas the center shaft 36 can be moved longitudinally with reference to the eccentric 34 while the latter is prevented from so moving by wings 38, guided by ends of two of the three bearings 39, 39D, and 39, in which the centery shaft 36 is journaled.l ln a similar way, the driving gear wheel 40 which'is driven by a suitable train of gears, not shown, from the main engine crank shaft is mounted upon the center shaft 36 by a spline 4l so that the shaft is free to move longitudinally while gear 40 is notallowed any longitudinal movement by two of the eccentric shaft bearings 39h, and 39C, adjacent to said gear, while at thesame time by reason of said spline 4l the center shaft 36 must turn with driving gear The center shaft 36 has a ball and socket connection 42 with link 43 so that shaft 36 is free to turn with reference to link 43 but has'its longitudinal position controlled by said link which is moved longitudinally by a mechanism to be described later. lt will be noted that when the center shaft is in the longitudinal position shown corresponding to position of ball and socket connection 42 which is marked SW and FW7 that the axis of the eccentric 34 upon the inclined cylindrical boss does not coincide with axis of said center shaft in its journals in bearings 39a, 39b and 39C, so that when the shaft revolves the eccentric 34, driving the plunger 3l through eccentric strap gives the plunger a stroke of twice the mean eccentricity of the axis of said eccentric 34 with reference to axis of shaft 36 in its bearings. On the other hand, when ball and socket connection 42 is moved by the link to position R4the mean position of the axis of the eccentric 34 will coincide with that of the axis of shaft 36 upon which it turns. Consequently the eccentric strap will ride conc-entrically with the shaft 36 and the plunger 3l of the fuel pump will remain stationary7 and the delivery of fuel oil to the engine will stop.

It will be further noted that for intermediate positions of ball and socket connection 42 between SM or Ft giving maximum stroke and delivery to fuel pump and position lt4 giving no fuel pump stroke and no delivery of fuel oil to the engine, any stroke and delivery of fuel by pump desired between Zero and maximum can be obtained.

The maneuvering` of engine is controlled by the hand lever H. In Fig. I, the power drive and the follow-up devicefbi7 which the main maneuvering crank shaft O is made to follow any movement of hand lever H is not shown, and this will be described and illustrated later. For the present the hand lever H may be considered keyed` rigidly to the maneuvering` crank shaft 0 as actually takes place when invention is applied to small engines where the power required to maneuver is within the limit of'manual effort. In Fig. I, the hand lever H is shown in opposite phase to a. crank 44 and pin 45 of the nmneuvering crank shaft O.

rllhe various stations for hand lever Hare represented` by the point-s SA, FA, RA, EA, EB, RB, FB and SB: SA to FA ahead startingsection, F A to RA ahead running section, RA to EA rock section, EA to EB endwise shift section, EB to RB rock7 section, RB to F B astern running section, FB

tinuing,

to SB astern starting section. Ofthese, the two rock and endwise shift sections comprise the reversing group of three sections, or broadly the reversing section.

Starting from RA stop station; for ahead motion if the hand lever H is moved to station SA, as shown in Fig. l, it will cause full fuel to be supplied to the cylinder and will put the starting valve 'l into operation and open shut off valve 4. When this has caused the engine to start, the hand lever fl should bemoved back to station FA if full power ahead is desired. This operation cuts out the` shut ofl' and starting valves. lf it is desired to run engine at less than full power, the hand lever H is moved more or less towards the stop station for ahead inotion BA, giving a corresponding reduction in the fuel supplied and consequently in the power and speed of engine.

If on the other hand starting from the stop station BA, the hand lever H and maneuvering crank shaft (l are moved in the opposite direction, the mainlay shaft 7 4 will be turned or rocked, so that cani rollers for fuel, air inlet and exhaust valves will be disengaged by the time the hand lever H reaches station EA. Continuing the mot-ion from EA to station FB will cause the main cani shaft 18 (driven by a train of gears, not shown, from main crank shaft at one half engine speed since engine shown is of four stroke cycle type) to move endwise sufficiently to bring all the cams on this shaft, for astern motion of engine, opposite their respective rollers. Still con the motion to BB station. will rock back the main lay shaft 74 causing their respective cam rollers to engage all the astern motion cams on shaft 18 except the starting cam rollers. Moving the hand lever fl from station BB still further to stations FB and SB and back to FB will have same effect as described above for moving from BA to SA, and back to FA except that the motion of main crank shaft will be in the reverse direction. Similarly motion of the hand lever H from station RB through EB and EA to RA will cause cam rollers to engage ahead ruiming cams instead of astern running cams.

The details of mechanism for the rocking of main lay shaft 74 and endwise shifting of main cam shaft 13 will be described later.

In Fig. the details of mechanism for controlling the supplly of fuel to engine and the starting of engine only are shown.

By a succession of wrist plate effects (such as have already been described in a general way) the starting cam rollers are rocked into engagement with their respective cams and the opening of starting air valve after suoli engagement. is made to take place while the hand lever is moving from FA to SA or from FB to SB, and. reversely when the hand lever is moved from SA to FA or from SIB to FB, the starting air shut off valve 4 is first closed and the starting cani rollers rocked out of engagement, closing the starting valves. During travel of hand lever H from FA through RA, EA, EB, RB, to FB or the reverse of this travel, the starting cam rollers are kept disengaged and the starting air shut off valve is kept closed. f

Starting lwith the crank pin on maneuvering crank shaft (l, the train of mechanisin is as follows: Link 46 drives rocker arm 47 pivoted at fulcrum 48. It will be noted that for both stations SA and SB of handle H the corresponding position of the link end of rocker arm 47 is the same, namely, at S1, for stations FA and FB it is at F1, and for RA and RB it is at R1, and the extreme position is at M1. Rocker arm 47 drives' through link 48, the rocker arm 49 pivoted at fulcrum 50 and the positions of the, link end of arm 49 corresponding to the hand lever stations are at S2, F2 and R2 respectively, with extreme position at M2.

y Following through lthe train of mecha nism we have link 51, driving rocker 52 pivoted at fulcrum 53 having its link end positions, S3, and R3 corresponding to the hand lever stations having same first letter and its extreme of travel at M3. Thence link 54 drives rocker 55 pivoted at fulcrum 56 and having corresponding positions for its link end at S4, F4, and Rtand eXtreme position at M4. Thence link 57 vdrives rocker 58 keyed rigidly to starting lay shaft 15 and having positionsfor one end thereof at S5, F5, and R5, which is also position of extreme travel, all corresponding to hand, lever stations having same first letter. Keyed rigidly to this same starting lay shaft i5 are rocker 16 connected to cam roller 11 as already described and rocker 59 operating the slotted link 22 connected to shut off valve 4 as already described.

lt will be noted that while the distance between SA and FA or SB and FB stations is very small compared to entire motion of hand lever H, for the corresponding stations of the rocker 58 on the starting lay shaft 15, the distance between S5 and F5 comprises almost the entire motion, the remainder be tween F5 to il being too small to present any difficulty.

It will be noted that the same train of mechanism as that used for the starting op eration just described is used for the fuel pump control as far as rocker 52 which has a short arm 60 having corresponding to the hand lever stations, link end positions SS, F3, and RB with asniall negligible overtravel beyond B73 to l 3. In the motion transmitted thence through link 43 to ball and socket connection 42, the wrist plate effect has been placed at other end of travel llO from those preceding inthe same train-'so that stations S4 'and F" are brought to same :point and-thedistance between R* and E4 'comprises substantially the entire end- Wise travel 'of fuel pump shaft36, and consequent oon'trol of amount of fuel delivered tofengineas'already described. Moving the hand lever from EA or 'FB to SA or SB stations respectively therefore does not affect the fuel pumpdelivery which is changed from full-'load to zero `gradually by moving' hand lever from `FA -or EB to RA or stations respectively.

yIn Fig. Il is shown tra-in of mechanism controlling the A'operation of rocking the main lay shaft 15, as already described in general terms.

'It will be noted vthat Vawseparate crank 61 is `provided on the maneuvering crank-shaft O Aand located opposite to the crank 4:4 `(in Fig. ll) on the same crank shaft but in same phase Withhand lever H xwhich in this view is shown at -station RA. i

Following `the vtrain A'of Imechanism beginning l-with the-crank pin k'62, fthe motion is transmitted through link 63 to t'rocker 64 pivot-ed at fulcrum 65, and the rocker y'has link end positions corresponding to "the hand lever stations, of saine first letter at TSSl, RR1,'and E?, the latter substantially at the extreme of travel. Y Then link l66 drives rocker 67, vvpivoted Aat fulcrum 68, said rocker having link end positions of corresponding stations, at SS2, RRZ and E2, then through link "69 to rocker 70, pivoted at fulcrum 71 said rocker having llink end positions-ofcorresponding stations, at E3 land BB3, vwith only a slight -over travel outside of each, thence through link 72 to rocker arm 73, keyed rigidly to main lay shaft 74, said rocker arm 73 vlia-ving positions `for corresponding'stations at E4 nearly at one eX- treme of travel and 'RR4 lexactly at other extreme. Keyed to lay 'shaft 74; is 'the shorter rocker 'arm 75 Vconnected through link`76 to Arcac'h -rod 77. l-Vith'hand tlever at station 'BA and rocker arm `73 in position HB4, as shown, the cam 7 8t on cam shaft 18 ivill engage -cam 'roller `79 and through link 77, rocker 80 pivoted at fnlcruni 81 and-stem 82 open at proper time the valve 88, Which is spring closed Iby spring 84:.

The cylinder head is drawn Awith an offset section which will make 83 represent equally Well `an exhaust-or air inlet valve according as the offset section shown 1isbehind or in front of center xline of the cylinder. Simijlarly'i will represent either-exhaust or air inlet cage and seat and 86 either air inletor exhaust pipe. y

It will be noted thatin this train of mechanism the travel of hand lever 'from EB to EA is almost entire-ly suppressed by the effect of vthe crank 61 and llink 68 and that three wrist plate effects in series aroused to suppress fall motion Iof [main lay shaft '74 during traveliof hand lever'betiveen SA and RA and between SB 'and RB 'since between all these latter stations all therunning -positions of engine occur during which theoam rollers must fhe held in proper position on the cams.

'ln Fig. 'III is shown train of mechanism controlling the operation'lof `endivise shifting of cani shaft 13 asalready described in general terms. lt will be noted that in this View the handle H is 'shown at station EA and that a 'crank pin 87 vis `provided on the underside ofthe .same Vcrank 61 as rshown in Eig. Il.

7from the crank pin 87 link `88 drives rocker 89 pivoted at fulcrum 90, Whichl through link 91 drives rocker-92 ypivoted at fulcrum 93, thence link 94- to rocker 95 pivoted at fulcrum 96, thence link 97 to rocker 98, :pivot-ed at ful-Crum *99, from which link 100 drives Vthrough the universal joint 136 ythe vrocker arm '101, the Aend only of which is shown in Fig. IH. Fig. V, Va projection Lat right angles to Fig. lll,'shows rocker 101 fixed to shaft 102 mounted in a bearing' y108 :(see Figlll) and having lined thereto a 'forked arn 10e for engaging through trunnion pins a collar 105 `rotatable upon 'cam shaft 13 but held from end- Wise movement on said shaft by flanges 106. In this manner the cam shaft 13 maybe moved end'vvise (the driving gear for said cam shaft not shown being' yprovided with sufficient length of gear face to permit such movement) by shift of trunnion pins from station EA;5 to EB5 When fthe hand lever l1 vis moved from station EA to EB or vice versa., and no endwise vmotion Whatever of thecam shaft'l will take place when the hand lever is ,moved from stations EA to SA and from EB to and vice versa.

This Will be apparent from considering the several positions of the'connecting links and rockers from handle H, the positions'of said rockers being indicated to correspond with the station positions lEA and EB of handle H.

lt Will be noted that the position of link 88 is nearly at right angles to that of link 63 in Eig. ll, in order to suppress in `motion of rocker 89 as muchas possible. the motion of the handle H from sta-tions EA to SA and from EB to SB. It Will be Anot-ed that the over travel of rocker 89 beyond position EAB is greater than beyond EBl. The motion of the rocker 92 has the over travel beyond EAB reduced to much less than 'beyond EB2. The motion 'of 'rocker l95 has the over-travel beyond EB3 less than beyond EAS. In the motion of rocker 98 fthe 'over tra-vel 'beyond EA* is still 'further reduced to a negligible amount, and the over travel beyond 'EB is vpractically, suppressed. Referring to Fig. V, the motion of rocker 101 has the over travel beyond E135 entirely suppressed as Well as that beyond E115.

It Will be noted that the intermittent inotions achieved in the various operationsi above described could be accomplished by a driving element having al forward and return motion, either circular or-ef translation, and equipped With a number of actuating cams of suitable form for various operations. The construction shown is eferable, however, since it can be operated more smoothly and quickly, and with much less power due to lessv friction involved; also While it involves a` Greater number of parts they are much more easily and cheaply made and kept accurate. By using most of the fulcrum pins in common, and placing the various trains of mechanism side by side upon them, and using a large number of duplicate links, pins, etc., as can be arranged in actual construction, a very compact arrangement, easily and cheaply fabricated is secured.

Fig. 1V and Fig. 17 show a device for changing the period of opening of fuel valve 107 measured in terms of degrees of rotation of main crank shaft y' (Fig. 17 is a project-ion in a vertical plane at right angles to that of Fie'. 1V, and shows some. parts that are in the latter for increased clearness. The parts in V are mounted on extensions of the front of engine frame I) which extensions are not shown in order to increase clearness of parts shown. 1t will be noted th at the upper part only of link 108 appears in Fig. 1V, and since the inclination of this link is at right angles to plane of projection of Fig. 1V, it is apparent in Fig. V only. For this reason the upper end of this link engages a ball and socket pin 109. lt will be noted that the rocker 110 upon an arm of Which this pin is mounted, has its arm slotted and the pin is provided with a shoulder on one side of slotted arm .and a thread and a threaded hand Wheel 111 on the other. rlfhis enables the position of pin to be adjusted radially on the arm Which has the effect of varying the amplitude of the arc through. vvhich rocker 110 swings synnnetrically with reference to its centraly position.

r1`he oil fuel is supplied through pipe 26 and is sprayed int-o cylinder by air, supplied through pipe 119. of a. considerably higher pressure than that in the cylinder. 'lhe amount of oil fuel which can be properly sprayed and the consumption of high pressure injection air depends on the area of the fuel valve opening and the period of time during which it is open. 1f an engine runs at aA speed much belovv normal full speed the period of time that fuel valve remains open increases and the amount of oilv required 4per stroke is usually lessened so that obviously it would give gr ater economy in consumption of high pressure air, together with some other advantages, such as alo'lity to run slovver, if the time period and amount of opening of fuel valve were reduced from that necessary for full poiver and speed. Y

rThe ahead and astern fuel cams 113a and 113b are shown in proper position for a piston on head end center of Working stroke (see e Fig. l). making the enter-ing working faces of both cams conform to a circumference of a circle having its center coincide with pin 11/1 at upper end of fuel valve reach rod 115 then by swinging the reach rod and its cam roller out of neutral position toward the nose of cam that it is engaging, the time of opening of fuel valve vvill remain about at beginning of stroke of piston asis desirable in this type of engine but the amount of opening and its duration for a given speed of engine will be obviously reduced as is desirable for reasons given above. rlihe valve 10'? is operated through cam roller 110 carried on pivot 117 of reach rod 115, pin 1111, rocker 118, fulcrumed at 119, and rocker 120, fulcrumed at 121. r1`he position of cam roller 11? is adjustable relative to the cams 113n and 113b by means of link 122 connected to the rocker 110 and the different positions assumed by the upper end of said rocker 110 are from the center position C1112 identical with C1139., to either CXA@ or to GXBQ. 1t Will be observed that the locus of the different positions for the cani roller pivot 117 during these adjustments is dotted line LX substantially concentric with thek entering surfaces of cams 11?? and 113i. Nhen the parts are in neutral position as shown, valve 107 will have normal fuel opening when rocker 110 is at station @11312 but Will give reduced duration and amount of opening if rocker 110 is at station @X112 l-lovvever, engine is running in a reverse direction, the rocker 110 must be moved from neutral position (HB2 in a reverse direction to station @XE2 to reduce duration and amount of valveo opening. Therefore rocker 110 1must be moved from neutral position shown, and which gives full valve opening, to reduce duration and amount of valve opening and the movement'must be in opposite direc tions for ahead and astern rotation of engine. 1t will be noted that 110 is a fioating lvell crank rocker pivoted on thev main rocker 15211 rigidly fixed upon main lay shaft 741 so that when the latter is rocked to permit endwvise shift of main cam shaft 13, all of the mechanism for changing valve opening as Well as fuel valve roller cam Will be shifted out of the Way.

The adjusting lever .-71.0 is fulcrun'ied at 150 and for full fuel v:live opening is held in station G1, by suitable latch (not shown) and mayalso be similarly held at CX or at however,

various 4intermediate stations. rlhe oi lever zc when in the position Cl, as shown, it extended would pass through center oi pin 109 to which it is connected by tulcrum pin 125 lioating link 126, pin 12T and floating link 108. Pin 12? is also connected to some part ot the reversing mechanism that always assumes one definite position vlien engine is running with ahead rotation and some other definite position for asern rotation. As shown, this connection consists of link 128, pin 129 on rocker 130, pivoted at ''ulcrum pin 131, and prov'ded with a segment ot' a gear a gear segment on rocker pivoted at tulcrnm 133, the latter being connected by link 134 to -pin 135, inouned on rocker 101, already described. These connections are suoli Jthat when engine has ahead rotation pin 12"? will occupy station Clif-il and the upper end ot rocker 110 will be at Cini/l, shown since trunnion collar 105 occupies station EAI and when engine has astern rotation, and collar 105 occupies station E135, pin 12T will occupy station Clll and rocker 110 the station (HB2, the correct position for asteLn rotation, iull fuel valve opening, and which it will be noted is saine position as station C1142, when lever zc is at station Cl. 1i lever 71o is lined at station CX when collar 105 is in station EAS (ahead rotation) pin 12T will occupy station @K1 and rocker 110 will occupy station CXA? corr ct for ahead running and minimum duration and amount ot fuel valve opening. `When lever /zc is at station CX, and collar 105 is at station EB, pin 127 will be at station CXB and rocker 110 will be at station CXBZ, cori-ecb position for minimum fuel valve openings astern rotation, but diierent` for minimum position for ahead running. lit adjusting lever flo is placed at inter` mediate stations between Cl and CX obviously intermediate fuel valve openings will be obtained. It the conditions are such that the relation between the speed of engine and the torque developed by engine vary a good deal from time to time, a hand adjustment oi"- lever hc is advisable, but il' in general when speed falls oil, the torque runs down and vice versa, an arrangement is advisable to automatically change fuel valve openings with change ot' engine torque which of course varies with stroke of fuel pump. rlheretore, the desired change can be accomplished by connecting lev r lic with fuel pump control mechanisms. This connection may consist ot a pin 137 on the lever ha for detachable engagement with a hooked link 138 pivoted on bell crank rocker 139, rigidly lined on a cross over shaft 140, and having an arm connected to a link 141. The link 141 is connected to a pin 142 on the link 43, as shown in Fig. I and Fig. la. The upper part of link 141 appears only in only n, .b The pivotal connections 142 and 143 at the upper and lower ends of link 141 are both ball and socket joints since they are connections to rockers swinging in diiierent planes.

While the speed and torque may always vary together, the rate ot change may not be the saine L both. ln this event the pin 109 can be adjusted by hand as already described so as to reduce the amplitude, on either side olf the normal full load posi` tion, as the case may be, of movement of rocher 110 and consequently pivot 117 for a. given movement of lever /w from station C1' and thus compensate for difference 'in rates or changes mentioned.

Fig. Vl and Fig. VII show details of a power drive with suitable follow-up mech anisin which may be employed in place ot having handle H connected directly to the maneuvering crank shaft O. The hand lever mit is here shown attached to the rim ot a wieel z-r turning loosely upon the maneuvering drive shaft O. rEhe various stations are in the same angular positions as shown with manually operated lever H in Fig. l, and hand lever mlb may be provided with a latch (not shown) which will engage various notches for various running positions between stations FA and RA and between FB and RB with a stop to prevent over-running starting positions SA and SB, all of which is actually provided with manual lever H in Fig. I, but omitted in drawing tor the sake of clearness. Upon the inner circumference of rim iw is fastened a single tooth 157i of an ordinary intei-nal spur gear. This engages the corre.- sponding recess in the switching plate m7@ proiiled to the ordinary shape of recess between adjoining teeth of an external spur gear. The plate mit is pivoted upon fulcruin pin mg which is carried by an arm mj attached rigidly to maneuvering shaft O. The position which plate m70 assumes after tooth th has passed itin a clockwise or in a counter-clockwise direction is shown in Fig. VIII and Fig. IX respectively. It will be noted that form of plate is such that it is locked in either position against casual turning by suitable guide faces abutting the rim 7W.

In Fig. VII mf is a master switch fastened to plate m70 so as to turn with it on fulcrum pin mg. When plate mk is in position shown in Fig. VIII a contact segment ot master switch mf will engage insulated contact spring ea. mounted on arm mj and when plate m/c is in position shown in Fig. IX, a. segment or'I mf will engage insulated contact spring eb. In order to secure proper kmotor control with the equivalent of a two pole double throw switch, two insulated contact segments like mf each with two c0n- Fig. l, while lower part ol" link 141 appears une Y? tact surfaces, and two pairs of contact springs like @a and e?) may be provided.

Electrical connections (not shown) be# tween master switch mf, contact spring eel, contact spring eb, electric motor m, and some source of electric'powerr (not shown) are so disposed that if hand lever mit and tooth H1.. are in neutral engagement with plate mit, andare moved in either direc tion, the resulting closing of electric cir cuit by master switch mi will cause the motor fm, driving thrmighpinion mcmounted rigidly upon motor shaft m17), to turn gear wheel fmul in a direction following motion of hand lever /m-t, and with it maneuvering crank shaft O to which it is rigidly attached, and together with it arm my', and crank pins 4:5 in Fig. I, (32 in Fig. II, and 8T in Fig. III. After the hand lever 'mit has been put in the desired position and the plate nr/ri has caught up and engaged the tooth H2, the master switch 'mf will be moved into neutral position, the circuitbroken, and the motion of maneuvering crank shaft (l will cease. In this way any movement. of hand lever '11th, is at once followed by a` movement of maneuvering crank shaft identical in direction and amplitude.

lVhile in actual practice, electrical refinements are added such as use of relay currents and contactors, dynamic braking to prevent over-ruiming of motor, etc., they add nothing to the invention outside of summation of their well-known advantage and are not shown.

Full automat/c control.

The :foregoing does not give a completely automatic control by a single lever and a power driven follow-up mechanism, such as eventually will be highly desirable, and especially when the engine control is directly operated from the bridge for which my invention is particularly suitable. In the fore going, when the maneuver involves starting of 'the engine, it is necessary to hold hand lever at starting station until engine has started properly after which it can be moved to station calling for the running condition desired. l

The above plan has been described first since it will make easier a clear description of additional necessary devices for full autoinatic control where hand lever can always be put at once at station calling for running condition desired.

These consist of a mechanism for throwing out the follow-up control when hand lever is moved out from either stop position 11A and RB. and also for causing maneuvering crank shaft O to continue motion to corresponriling extreme or starting position SA or SP). and stop, and another mechanism consisting of a device for putting the follow-up control in gear, yafter the engine has 'switch svn/7m, to be described later,

made a sufficient number of turns to insure proper starting. Vnince the crank shaft has over-run the running position of hand lever,

the effect of throwing the follow-up control into gear will loe to bringithe crank shaft back to station corresponding to that of the hand lever, giving the full automatic control with the single lever desired.` The devices for the foregoing are illustrated in Figs. X to XVI inclusivee-Fig. XI being a horizontal section, the others beingvertical sections taken at different points. In these further views, the parts similar to lthose sho-wn in the foregoing drawings are designated by the saine reference characters.

In Fig. X and Fig. XI, is shown an arm my fixed to the shaft O and having a switch mf pivoted at mg similarly to that on' arm my', shown in F VII. It will be understood that the hand wheel ha" and handle mh are here provided. as shown in Fig. XI, which also shows the latch mha, not shown in Fig. VII. The tooth Hr. of this hand wheel engages a similar switch plate mk hxed to the shaft mg on arm my. Arm my" has an extension mjc in opposite phase and provided similarly to my" with a shaft ing/c upon which is mounted insulated contacts mfc and switch plate mk@ (see Figs. XI and XII), both mounted so as to turn with the shaft myc. It will be noted that the phase of the positionof the shaft my@ is always opposite that of mq. If the arm my" moves from the stop station RA as shown in Figs. X, XI, and XII, toward starting station SA, the plate mico having the guide face ogm in contact with theguide surface on casing l) will be shifted by engaging the tooth Hrm so that `the guide face ogm will comeincontact with the guide surface `of casing 7) as shown in Fig. XVI. This will shift the contact surfaces of plate mfc so that instead of contact springs ecm being in contact as shown in Fig. X, ecc will be in contact as shown in Fig. XV. It should be noted, however, that, since the latch arm of will at this time be disengaged the position of switch .9m/7m will be as in Fig. X with contacts casa engaged instead of as in Fig. XV. The contacts @ma are in series in the same circuit that passes through 4contacts 60a which circuit herein termed a secondary control circuit, is independent of the primary follow-up control circuit containing the conV tacts @a and e7), `and when closed operates the motor to cause arm my" to move 1n a clockwise direction independently of position of handlemh. The circuit passing through ecm is in series with the primary control circuit passing through either contact err or e?) whichever may be engaged with mfg to operate the motor for causing my" to follow the handle mit as was described in connec-` lfion with Fig.. VII. Therefore, breaking this contact com will disengage the primary y tion and n; ,runt

follow-up control and the circuit passing through contacts cca and contacts @am which will be closed.l will cause the arm mj to revolve in a clockwise direction, as already stated.A This will continue until the arm mj reaches the starting' station SA when the inner guide face ga, of plate m/ac will eng'aoje a tooth z/saupon an inner guide surface 00p/a which will turn the plate m/cc into the position shown in F XIV with contacts cca and ccm, both disengaged as shown in Fig. XIH. lt is obvious that an overrunning in either direction will tend to return the arm my" to station SA because the shifting of the plate ffm/20 will close the circuit to produce this effect in a similar manner to the follow-up control previously described. In order to avoid any break in the motion of the arm mj when it leaves station RA and moves towards SA at the time the tooth Him engages the plate art/cc, an insulated contact piece firrjr attached to the gear wheel md as shown on Figs. X and XI, will engage the contact spring am mounted upon a xed block crus. rThese complete a circuit in multiple with the primary circuit passing;` through the contact com. The length of the contact piecemf/'r is limited so that it will cease to function after contact springs am have engaged.

lVhen the arm my" reaches station SA, it will cause engine to start as previously described.

The translating` device for restoring the primary followup control into operation after engine is started is shown mainly in Fig'. X. maa is a shaft driven through a suitable train of `gears not shown, so that it will revolve at engine speed or in some definite ratio to that speed. This shaft by means of bevel gears msba and meca drives a shaft msec mounted in bearing msc/la, mounted upon maneuvering` casing` A similar pair of gears met?) and mac?) drive a similar shaft mad). The latter shaft functions only wheustarting the engine in astern direction. while the former functions when starting the engine in an ahead direction. At thelower end of shaft msm is a jaw clutch. -inline vwith this is a shaft maga provided at its upper end with an engaging clutch msi/'en This shaft maf/a at its lower end is provided with a groove-d sleeve mami held in place by the removable flange maf/,uc fastened to shaft msg/a upon which the sleeve mam is free to move longitudinally except that it is normally held against the collar 'mm/fu; by the spring msu@- pressing;` against the colla maui-'a fastened upon the shaft magri. The link msi/a is of square seccd in hearings msg/Zia in such a manner tha n: cannotpturn but is free to move endwise. This link is forked at its upper end and engages the trunnion pins of trunnion mama. It is also forked at the lower end and provided with a roller msm. The arm my" is provided with two inclined wings mja and mjb, as shown. lVhen the arm mj approaches the position corresponding to'station SA, the wing mja will engage the roller msm lifting the shaft msg/'a so that the half clutch 'ms/fn, will engage the half clutch'msea causing the shaft maf/a to turn with the engine as long` as the roller mss@ engages the wing' mja. The clutch engagement is a yielding one due to action of spring)` msua. There is also a collar msg/fu, fixed upon shaft may/a. with a spring may/aa between said collar and the upperl liearing` rmsi/71a to insure that when the wing mja recedes from the roller masa the clutch will discngage.

The shaft mega. is guided in a sleeve msm which in turn is threaded and guided in the nut ms/ea lixed to the maneuvering casing t). The shaft msg/J, is free to move endwise in this threaded sleeve but is prevented from turning' by the spline msj/a. The action is such that when the engine turns in a forward direction the sleeve turning in the nut will move downward. At the vlower end of this sleeve is provided an annular groove in which is situated .free to turn a trunnion block melia. A lever msm/z pivoted at mana is provided with a forked end which engages the trunnion pins msLu. This pivoted lever mama is provided at its-outer end with al pin mapa to which at attached a strong spring msm 'fastened at its other end to the stud msm. mounted on the casing` b. The thread on the sleeve msz'a is made with a. sufhciently rapid pitch so that when the clutch maf@ is disengaged the action of this spring msm will cause the sleeve to assume its uppermost position. The lever mama is also provided with a pin mscaconnecting to the link asa. Y

When engine has started, and link ma lifts, it will operate the switch ism/ca., pivoted at fsm/na, to which it is connected by the pin pam, upon the arm of switch smi/cu., engaging they lower end of slot in link asa. This will change these mechanisms from the positions shown in Fig'. X to the positions shown in Fig'. XIII. It will be'noted that by varying the position of the lower end of this slot, the number of revolutions which the engine makes after starting, before link as@ engages pin 7mm, can be varied as desired, in order to insure a proper starting of engine before operating' the switch smfu. The operation of this switch disengafres the contacts enen, which are in series in the secondary control circuit passingthrough con facts een. and closes the circuit of contacts riz/17m which is in multiple with the primary circuit of contacts ecm, both of which are in series with the circuitof either contacts @a or eb on Fig. X. This therefore, 

